Projects per year
Abstract
The adoption of electric vehicles (EVs) with lithium-ion (Li-ion) batteries is steadily increasing. The performance,
efficiency, and safety of Li-ion batteries rely significantly on thermal management systems (TMSs). This study
investigates a novel hybrid TMS, combining aluminum plate, phase change material (PCM), and liquid cooling,
to cool the battery module. A passive PCM heat buffer plate and liquid cooling plates are strategically positioned,
with the former placed below and the latter on the sides. The temperature of the module has been considered
under the 4C and 8C charging rates and using different cooling methods. Natural convection cooling alone fails to
maintain the module temperature within the desired operational range during fast charging. The maximum
module temperature during charging for 4C and 8C peaks at 42 ◦C and 58.5 ◦C, respectively. However, incor-
porating a PCM heat buffer plate reduces temperatures to 36.3 ◦ C and 49 ◦C by the end of charging, marking
reductions of 13.5 % and 16 %, respectively. With the hybrid cooling system, temperatures further drop to
31.2 ◦C and 38.4 ◦C by the end of charging, representing reductions of 25.7 % and 34.3 %, respectively,
compared to natural convection.
efficiency, and safety of Li-ion batteries rely significantly on thermal management systems (TMSs). This study
investigates a novel hybrid TMS, combining aluminum plate, phase change material (PCM), and liquid cooling,
to cool the battery module. A passive PCM heat buffer plate and liquid cooling plates are strategically positioned,
with the former placed below and the latter on the sides. The temperature of the module has been considered
under the 4C and 8C charging rates and using different cooling methods. Natural convection cooling alone fails to
maintain the module temperature within the desired operational range during fast charging. The maximum
module temperature during charging for 4C and 8C peaks at 42 ◦C and 58.5 ◦C, respectively. However, incor-
porating a PCM heat buffer plate reduces temperatures to 36.3 ◦ C and 49 ◦C by the end of charging, marking
reductions of 13.5 % and 16 %, respectively. With the hybrid cooling system, temperatures further drop to
31.2 ◦C and 38.4 ◦C by the end of charging, representing reductions of 25.7 % and 34.3 %, respectively,
compared to natural convection.
| Original language | English |
|---|---|
| Article number | 112994 |
| Pages (from-to) | 1-11 |
| Number of pages | 11 |
| Journal | Journal of Energy Storage |
| Volume | 97 |
| Issue number | 112994 |
| DOIs | |
| Publication status | Published - 10 Sept 2024 |
Bibliographical note
Funding Information:The presented study was developed under the structure of the SELFIE project which was granted from the European Union's Horizon 2020 research and innovation program under Grant Agreement Nr. 824290. Moreover, the authors acknowledge \u2018Flanders Make\u2019 for the support to the MOBI research group.
Publisher Copyright:
© 2024 Elsevier Ltd
Keywords
- Lithium-titanate-oxide (LTO) battery
- Thermal management system
- Phase change material
- Liquid cooling system
- Hybrid cooling system
Projects
- 1 Finished
-
EU588: SELFIE: SELF-sustained and Smart Battery Thermal Management SolutIon for Battery Electric Vehicles
Van Mierlo, J., Omar, N., Berecibar, M., Asanova, S., Jaguemont, J., Akbarzadeh Sokkeh, M., Behi, H., Karimi, D., Kalogiannis, T. & Boursot, I.
1/12/18 → 31/07/23
Project: Fundamental